A manually-operated device for safely inflating automotive vehicle tires. A pressurized gas cylinder is connected to a manual valve for delivery of pressurized gas to a vehicle tire. The gas pressure is safely controlled (regulated) by a stepped piston that is slidably arranged in a vent chamber. A small diameter rod section of the piston is aligned with a valve seat in the main flow passage. pressure rise on the large diameter section of the piston causes the rod section to temporarily interrupt the main gas flow. Gas is vented around the large diameter section of the piston to enable the rod section to move away from the associated valve seat, thereby permitting gas flow to resume through the main passage.

Patent
   4969493
Priority
Jan 17 1989
Filed
Jan 17 1989
Issued
Nov 13 1990
Expiry
Jan 17 2009
Assg.orig
Entity
Small
42
22
EXPIRED
1. A supplemental tire inflator comprising a pressurized gas cylinder; means forming a tire-inflation passage (22, 23, 37) extending from said pressurized cylinder; a manually operated valve (50, 52) controlling gas flow through said tire-inflation passage; a valve seat (36) in said tire-inflation passage downstream from said manually-operated valve; and means (at 6) for regulating the pressure of the gas after passage across the valve seat; said pressure regulating means comprising an atmospheric vent chamber (35) isolated from said tire-inflation passage; a stepped piston (60) that includes a large diameter piston section slidably mounted in said vent chamber, and a small diameter piston section (61), extending through and beyond said vent chamber; a pressure control passage (38) communicating with said tire-inflation passage downstream from said valve seat (36); a pressure-reducer valve means (63, 64) in said pressure control passage; said large diameter piston section having an end face exposed to said pressure control passage; said small diameter piston section having an end face axially aligned with said valve seat for interrupting gas flow therethrough when there is a pressure build-up in the pressure control passage; and means (at 40) establishing a leakage path around the large diameter piston section for temporarily relieving the pressure on the end face of said large diameter piston section.

This invention relates to a manually-operated device for inflating a vehicle tire. For safe driving, it is very important to keep the car tires at a suitable pressure determined according to local climate, car model, and regular driving speed. If the car tire pressure is excessively low, while driving under high speed, the friction resistance will be increased, and therefore, steering control will be more difficult. Also, the car tires will tend to wear prematurely. When a tire (high-speed tire) is pierced by a nail to exhaust, the tire should be replaced by a spare tire. If no suitable spare tire is available, the driver will have to inflate the tire by oneself or contact a maintenance shop for tire repair or replacement.

A car maintenance shop will have a pressure gauge for checking the tire pressure. However, the ordinary car driver will not have a pressure gauge to accurately control tire pressure while using a tire inflator to inflate the tires. In consequence, car tire pressure may be over or below the normal optimum range when the car owner inflates the tire.

The present invention is related to a supplementary car tire inflator comprised of a high-pressure CO2 cylinder, a manually-operated valve, a stabilivolt output device, and an outlet valve, wherein said stabilivolt output device is adapted to control the air pressure during inflation of the tire so as to prevent the tire from being blown out due to excessively high pressure. The outlet valve includes a pressure exhaust valve to control the air pressure applied to the tire. Therefore, the tire pressure can be controlled within a suitable range while using the present invention to inflate a tire.

While driving, if a car tire is pierced by a nail, the present invention can be utilized to inflate the tire for continuous driving for a reasonable period of time so as to let the driver have enough time to look for a car maintenance shop to patch the tire.

FIG. 1 is a sectional view of the supplementary tire inflator constructed according to the present invention.

FIG. 2 is an elarged schematic drawing of a CO2 cylinder used in the FIG. 1 structure, showing its pierced condition.

FIG. 3 is an enlarged sectional view of a manually-operated valve used in the FIG. 1 structure.

FIG. 4 is an elarged sectional view of the stabilivolt device used in the FIG. 1 structure.

FIG. 5 illustrates the stabilivolt device of FIG. 4 in its closed condition .

Referring in greater detail to the drawings, FIG. 1 shows a supplementary tire inflator comprised of a housing 1, a CO2 cylinder 2, a manually-operated valve 50, 52, a stabilivolt device 6, and an output device 3.

The said housing 1 is comprised of an upper shell 18 connected with a lower shell 19 by means of a screw joint indicated by numeral 20. A high-pressure CO2 cylinder 2 is disposed within the lower shell for engagement by a needle tube 10 designed to pierce through the top end surface of the CO2 cylinder (as shown in FIG. 2). Cylinder 2 will be screwed onto the upper shell before the lower shell is screwed onto the upper shell. As cylinder 2 threads into the associated threads in the upper shell the hollow needle 10 pierces the end wall of the cylinder. Needle 10 acts as a fluid connector between cylinder 2 and a passage structure 22 in shell 18.

The upper shell serves as a mounting structure for a manually-operated valve 50, 52 and the stabilivolt device. A hose 4 is connected to the coupling 11 of the said stabilivolt device for communication of the said stabilivolt device with the output device 3. The output device 3 is adapted to screw onto an intlet valve, not shown, of a car tire.

The manually-operated valve is comprised of an L-shaped drive plate 50, a push rod 51, and a check valve having a spring 53 and a steel ball 52. The L-shaped drive plate 50 is designed to drive the push rod 51 to push the steel ball 52 away from the valve port as shown in FIG. 3, so as to let CO2 gas flow through the associated passage 23 into the stabilivolt device 6. There is provided a slide block 54 to stabilize the L-shaped drive plate 50 so as to provide maximum safety. The stabilivolt device 6 includes a stepped piston 60, and a constant-pressure control valve comprised of a spring 64 and a steel ball 63 (FIGS. 4 and 5).

The cross sectional area of piston 60 is different at its opposite ends; i.e. the main body of the piston 60 has a relatively great cross sectional area, whereas the rod portion 61 of the piston has a lesser cross sectional area. The large diameter section of the stepped piston is slidably mounted within a cylindrical vent chamber 35 that contains a spring 66 therewithin. The rod portion of the piston extends through the vent chamber toward a valve seat 36 in the main flow passage.

A piston ring 65 is mounted on the separating (isolation) wall between the vent chamber 35 and the main flow passage 37. Spring 66 is set within the range of the stroke of piston 60, and a pressure outlet tube 67 is provided to communicate the vent chamber with atmosphere. There is also provided an abutment member 69 to limit motion of piston 60 away from piston ring 65. Control valve 63 is located in a control passage 38 that leads from the main flow passage 39 to the large end face of piston 60. A flow tube 37a connects a passage 37 to coupling 11 (FIG. 1).

In the stabilivolt device, when the output pressure of the C02 gas exceeds the pre-determined range for the said resilient steel ball 63, the steel ball 63 is forced to break away from the associated valve port, as shown in FIG. 4. The control gas flows through passage 38 against the end face of the large diameter section of piston 60 to apply a force thereon.

Assuming that:

Output pressure of the gas from the CO2 cylinder is P1; Compression strength of the steel ball 63 is P2; Sectional area of both ends of the piston 60 are A, aA (a>1); thus, the pressure the large diameter section of piston 60 is bearing shall be P1-P); the total pressure the piston rod 61 is bearing shall be P1×A; the total pressure the piston body 60 is bearing shall be (p1-P2) ×aA;

If (P1-P2) aA-P1A>0

thus (P1-P2) a-P1>0

thus P1>(a P2)/(a-1)

Thus, the piston will be displaced to cause rod section 61 of the piston to engage the associated valve seat 36, to thus block flow through the main passage 37 as shown in FIG. 5. When the main flow passage is blocked by the rod section of piston 60, gas will be exhausted from the end face of the large diameter section of the piston body 60 through a peripheral gap 40 between the piston and the wall that forms the vent chamber 35. Gas in the vent chamber 35 will be exhausted to the atmosphere via pressure outlet tube 67. Therefore, the inner pressure of the said stabilivolt device remains at a satisfactory low level, and the gas from the CO2 cylinder is allowed to push away the piston 60 to let the conduit be opened (as shown in FIG. 4). The process is repeated again and again to secure the output air pressure below a fixed range. Further, a plurality of circular grooves 68 are made on the pistion 60 to stabilize the stroke and to minimize the mechanical resistance (resistance of friction).

The output device 3 includes an air valve 31 having a nut 30 set thereon with an 0-ring 32 set therebetween. When the nut 30 is connected to the inlet valve of a car tire, the 0-ring 32 is adapted to prevent any air leakage. The output device 3 may be arranged to provide an exhaust valve 33 and a pressure gauge 34. If tire pressure is over the fixed range of the said stabilivolt device, the inner pressure of the tire may be exhausted by means for said exhaust valve 33 to reach a preferred level measured by reading from the said pressure gauge 34.

According to the present invention, the gas from the CO2 cylinder is released to inflate a car tire under suitable pressure controlled by the said stabilivolt device. Therefore, explosion of car tires due to suddenly increasing the tire pressure can be effectively prevented. The device constructed according to this invention is very practical for inflation of tires under an emergency case when the car tire is pierced or exhausted; the fixed air pressure range for the stabilivolt device is slighlty higher than tire pressure, and the fixed air pressure range for the exhaust valve of the output device is equal to the tire pressure.

Lee, Tzal-Lin

Patent Priority Assignee Title
10251450, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
10683944, Jul 19 2018 Tire inflation pressure control device
11161482, Dec 16 2020 Air inflation tool
5146953, Jul 01 1991 Pipe sealing apparatus
5316055, Apr 19 1993 Bicycle tire recharge apparatus
5329975, Sep 22 1993 Apparatus for pressurizing containers and carbonating liquids
5407096, Nov 30 1992 Sherman Products Corporation Apparatus for providing a portable source of high pressure gas
5494083, Jan 03 1995 Utility air tank
5544670, Dec 15 1993 Reebok International Ltd; Innovations in Cycling Inflation device for an inflatable article of manufacture and adaptor therefor
5590696, Jul 14 1994 Reebok International Ltd Inflation system utilizing a pressurized gas inflation device and adaptor therefor
5607087, Sep 19 1994 Pressurized fluid dispensing device
5628350, Jul 13 1995 Raptor, Inc. Inflating device
5857481, Apr 17 1996 Tire inflation system and process
5884659, Sep 23 1996 Portable tubeless tire inflating system
5931185, Aug 08 1996 Black & Decker Inc Air hose storage assembly for inflators and method for handling an inflator air hose
6119513, Sep 07 1995 Bridgestone Corporation Method for endurance testing of pneumatic tires
6202714, Feb 09 2000 Air pump having space for containing air bottle
6785985, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
6889723, Jul 11 1995 Sumitomo Rubber Industries, Ltd. Preparation for sealing punctured tires and apparatus for the sealing and pumping up of tires
6911902, Mar 11 1998 Fuller Bros Inc. Pneumatically actuated mounting apparatus and method for a tire inflation gas parameter monitoring system
6988329, Jul 02 2002 Reebok International Ltd. Shoe having an inflatable bladder
7047670, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
7152625, Jul 02 2002 Reebok International Ltd. Combination check valve and release valve
7278445, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
7337560, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
7340851, Jul 02 2002 Reebok International Ltd. Shoe having an inflatable bladder
7445533, May 09 2006 Inflation device
7513067, Jul 02 2002 Reebok International Ltd. Shoe having an inflatable bladder
7587933, Mar 01 2004 Bridgestone Corporation Process for repairing punctured pneumatic tire in tire-rim assembly and repairing system
7721465, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
7735241, Jul 02 2002 Reebok International, Ltd. Shoe having an inflatable bladder
7878360, Jun 02 2005 Bridgestone Corporation Container for sealant for pneumatic tires
8037623, Jun 21 2001 Nike, Inc. Article of footwear incorporating a fluid system
8151489, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
8250782, Mar 26 2009 Reebok International Limited Valve for regulating pressure in a fluid system
8360119, May 20 2010 HUANG, YING-CHE High-pressure inflation pump
8677652, Jul 02 2002 Reebok International Ltd. Shoe having an inflatable bladder
8789730, Oct 16 2007 Backpack with collapsible stretcher and collapsible wheel assembly
8794258, Oct 05 2011 Pressure harmonizer
9248416, Sep 14 2012 Apparatus for the pressurization and evacuation of a container
9474323, Jul 02 2002 Reebok International Limited Shoe having an inflatable bladder
9856871, Aug 05 2015 Bicycle air pump
Patent Priority Assignee Title
1786103,
2001233,
2498596,
2761601,
2812783,
3448779,
3809288,
3996957, Sep 12 1975 MILTON INDUSTRIES, INC. Inflator valve with pressure gauge and safety regulator
4054163, Apr 19 1976 General Motors Corporation Tire inflator
4116245, Jul 13 1977 Combination tire inflator and pressure gauge
4168015, Apr 24 1978 CLIFF ACQUISITION CORPORATION, A CALIFORNIA CORPORATION Tire inflation device
4489855, Aug 27 1982 CODE MANUFACTURING INC , A CORP OF OHIO Instant tire inflator
4658869, May 07 1986 Combination tire inflator, gauge and deflator
4662412, May 13 1986 Peter, Bergmann; BERGMANN, PETER Inflating device for use single-handed
AT129404,
BE509789,
DE1113378,
DE3205264,
DE3237350,
FR13574,
GB332795,
JP136718,
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